By Luc Clément – @luclement
Until now, processing collections or tables in Java in a MapReduce manner was done mostly with the Iterator pattern. Java 8 introduces the Stream API to simplify this type of processing with a new Object: Stream
A stream is built from a data source (e.g. a collection, a table or I/O sources), and it has a few specific properties:
Two types of operation can be performed on a stream: intermediate and terminal.
Intermediate operations (e.g. Stream.map or Stream.filter) are done lazily and return a new stream, which creates multiple streams called stream pipelines. As long as no terminal operation is called on a stream pipelines, intermediate operations are not executed.
When a terminal operation is called (e.g. Stream.reduce or Stream.collect), all the streams created by intermediate operations are traversed, operations are applied to data, and the terminal operation is performed. Then every stream is consumed and destroyed, and cannot be used any longer.
Example of Collection processing
List<String> strings = Arrays.asList("giraffe", "cat", "camel", "fish", "whale");
strings.stream()
// filtrage
.filter(x -> x.contains("ca"))
// mapping : reformating of character strings
.map(x -> x.substring(0, 1).toUpperCase() + x.substring(1))
// alphabetical sort
.sorted()
// Outputs:
// camel
// cat
.forEach( System.out::println );
There are different ways to create a stream. The simplest way is to call the method stream() or parallelStream() on a collection. Another way is to call methods that were added to existing classes.
For instance, String’s method chars() returns an IntStream with the characters in the String, and BufferedReader’s lines() method creates a stream of characters from the lines of the open file. Interestingly, Random’s method ints() returns a stream of pseudo-random numbers.</>
The API also includes static methods in the Stream class. For instance, the following code “Stream.iterate(1, x -> x*2)” returns an infinite stream of powers of 2. The first argument contains the initial value of the stream, and the second the function to go from the element n to the element n+1.
One of the main advantages of the new API is the ability to easily parallelize processing. Indeed, any stream can be parallelized by calling its parallel() method inherited from the BaseStream interface. Any stream can become sequential with an invocation of the sequential() method. It is also possible to build a parallel stream directly on a collection by calling the collection’s parallelStream()’s method.
These methods conveniently abstract the work distribution, but they should not be used lightly: in some cases, parallelization can decrease performance (as shown further down with stateful operations).
Intermediate operations can be stateful or stateless. Stateless operations are applied to the elements of a stream independently – without taking into account other elements.
Collects allows us to easily store the result in a list
List<Order> myOrders = … ;
List myClients = myOrders.stream()
.map( c -> c.getClient() )
.collect( Collectors.toList() );
Stateful operations generally require knowledge of the full stream to get a result (e.g. Stream.distinct or Stream.sorted). Therefore, parallelizing a stateful process may decrease performance.
We deduplicate the list of clients with the intermediate operation distinct()
List<Order> myOrders = … ;
List myClients = myOrders.stream()
.map( c -> c.getClient() )
.distinct()
.collect( Collectors.toList() );
There are two types of reduction in the Stream API: simple reductions and mutable reductions.
Simple reductions are, for instance: Stream.sum (sum of elements), Stream.max (maximum) or Stream.count (count of elements). It is defined this way:
U reduce(U identity,
BiFunction<U, ? super T, U> accumulator,
BinaryOperator<U> combiner);
The identity element is the initial element for the reduction (and the returned element if the stream is empty). The accumulator creates a new partial result from the partial result and a new element, and the combiner creates a new partial result from the two partial results. Note two things:
We can use the reduce() method to rewrite the sum() method
List<Order> myOrders = …;
int revenue = myOrders.stream()
.reduce( 0,
(result, order) -> result + order.getPrice(),
(resultA, resultB) -> resultA + resultB );
Mutable reductions generalize this concept by accumulating the elements of a stream in a container. This container can be a Collection, a StringBuilder, or even a simple integer (in which case we would have a simple reduction).
<R> R collect(Supplier<R> supplier,
BiConsumer<R, ? super T> accumulator,
BiConsumer<R, R> combiner);
This syntax is similar to the reduce() method syntax. This time, however, we have to initialise a container (Supplier), then define the accumulator method that will add an element to a container, and finally define the combiner method that will create a new container from the two temporary containers.
In order to simplify our code, the Stream API also provides another class, Collectors, which encapsulates the three arguments necessary to a reduction for certain classical operations (e.g. fetching data in a list, map or set, concatenating characters). For instance, we can modify our previous code and get the same result:
List<Order> myOrders = …;
int revenue = myOrders.stream()
.collect( Collectors.summingInt( Order::getPrice ) );
This new JDK 8 API is going to fundamentally change the way we process Collections by providing an alternative to the cumbersome Iterator pattern. The new API benefits from the new lambda syntax to reduce code size while improving performance. Moreover, the Collectors class provides many patterns that will often replace the Iterator pattern.